Programmed DNA elimination in the parasitic nematode Ascaris

In most organisms, the whole genome is maintained throughout the life span. However, exceptions occur in some species where the genome is reduced during development through a process known as programmed DNA elimination (PDE). In the human and pig parasite Ascaris, PDE occurs during the 4 to 16 cell stages of embryogenesis, when germline chromosomes are fragmented and specific DNA sequences are reproducibly lost in all somatic cells. PDE was identified in Ascaris over 120 years ago, but little was known about its molecular details until recently. Genome sequencing revealed that approximately 1,000 germline-expressed genes are eliminated in Ascaris, suggesting PDE is a gene silencing mechanism. All germline chromosome ends are removed and remodeled during PDE. In addition, PDE increases the number of chromosomes in the somatic genome by splitting many germline chromosomes. Comparative genomics indicates that these germline chromosomes arose from fusion events. PDE separates these chromosomes at the fusion sites. These observations indicate that PDE plays a role in chromosome karyotype and evolution. Furthermore, comparative analysis of PDE in other parasitic and free-living nematodes illustrates conserved features of PDE, suggesting it has important biological significance. We summarize what is known about PDE in Ascaris and its relatives. We also discuss other potential functions, mechanisms, and the evolution of PDE in these parasites of humans and animals of veterinary importance.


Introduction
Ascaris is a parasitic nematode that lives in the small intestine of humans and pigs [1]. The human (A. lumbricoides) and pig (A. suum) parasites can cross-infect and have little difference in anatomy, physiology, and genome sequences [2][3][4][5][6]. For simplicity, we use Ascaris to refer to both species in this review. Ascaris was estimated to infect >700 million people worldwide in 2021 [7]. Most cases are found in impoverished children [8][9][10]. Ascaris infections (ascariasis) often have mild or no symptoms, but heavy infections can cause intestinal blockages and even death if left untreated [8,10]. Ascariasis contributes significantly to global disability-adjusted life years and perpetuates the cycle of poverty [9,11]. Ascaris is a member of the Ascarididae parasitic nematode family, known as ascarids, that infect a wide variety of vertebrates, including Parascaris univalens and P. equorum (horse), Toxocara canis (dog) and T. catti (cat), Baylisascaris procyonis (raccoon) and B. schroederi (panda), as well as Ascaridia galli (chicken). Deworming drugs are widely used to attempt to control Ascarididae and other parasitic infections [3,8,12]. However, recurrent drug treatment has led to drug resistance in nematodes of veterinary importance [8,[12][13][14]. Thus, new drugs are needed to fight the increasing drug resistance.

Overview of PDE
PDE was discovered in 1887 by cell biologist Theodor Boveri in the horse parasite P. univalens [42]. The P. univalens germline contains a single, large chromosome with 2 heterochromatic (HET) chromosome arms that are mainly composed of repeats (see below on the nature of eliminated DNA). Boveri observed that this single chromosome was fragmented during early embryogenesis in pre-somatic cells (Fig 1A). The resulting chromosome fragments were passed to the daughter nuclei, while the HET arms were eliminated from the reduced somatic genome [42] (Fig 1B). Since the discovery of PDE, single-cell ciliates and over 100 metazoan species from phylogenetically diverse groups, including nematodes, insects, mites, copepods, ratfishes, hagfishes, lamprey, songbirds, and bandicoots, have been observed to eliminate DNA [36,43]. However, within each phylogenetic group of metazoans, only a small percentage of organisms undergo PDE, suggesting PDE evolved independently among these groups [36,44].
Not surprisingly, the PDE processes are mechanistically diverse. In metazoans, there are 2 major types of PDE: (1) loss of an entire chromosome(s); and (2) fragmentation of chromosomes resulting in the loss of genetic material, coincident with germline-to-soma differentiation. The second form of PDE is particularly intriguing as it requires the generation of doublestranded DNA breaks (DSBs). Nematodes and ciliates are known to introduce DSBs during PDE [45]; based on cytological studies, other animals such as hagfish and copepods also likely break their chromosomes during PDE [46,47]. In single-cell ciliates, domesticated transposases are responsible for many of the PDE DNA breaks [48]. However, the mechanisms and machinery associated with the DNA breaks in metazoans remain largely unknown. More general descriptions and discussions on PDE in diverse organisms have been summarized in recent reviews [40,43,45,[49][50][51][52].
Ascaris remains one of the most extensively studied models for PDE in metazoans. Early work in Ascaris provided robust cytological and molecular data that revealed critical features of Ascaris PDE [37,44,53]. Recent genomics studies have expanded our understanding of Ascaris PDE to the whole genome at the chromosomal level [41]. These studies are in part facilitated by the large size of Ascaris and its enormous reproductive capacity [1] with large numbers of zygotes available from the uteri. These zygotes undergo synchronous development under laboratory conditions [1]. Their prolonged cell cycle (approximately 15 to 20 hours) makes it possible to isolate embryos at precise stages of development [54], including before, during, and after PDE. Although the parasitic lifestyle of Ascaris makes maintenance and genetic manipulation difficult, decades of molecular work in Ascaris have provided one of the most comprehensive understandings of PDE in a metazoan [6,45,49,50].
Recently, studies in the free-living nematode Oscheius tipulae have shown that it undergoes PDE [55,56]. In addition, cytological studies in the Mesorhabditis family of nematodes indicate that they also eliminate DNA during embryogenesis [57]. With more complete genomes, rigorous cytological studies, and comparative analysis on the differences in genome coverage between germline and somatic tissues, we predict more organisms with PDE will be identified in the near future [58]. The recent identification of PDE in free-living nematode species prompts questions about how frequently PDE occurs among metazoans (especially nematodes) and the selective advantage(s) it may provide. Free-living nematodes with PDE also present new opportunities to study PDE in genetically tractable systems [56]. These studies will complement work in Ascaris and provide comparative and evolutionary perspectives on PDE in metazoans.

Ascaris PDE breaks chromosomes and eliminates DNA
In most multicellular organisms, PDE events occur during early development during the germ-to-soma transition [45,49]. However, the exact timing of PDE varies among species. Cytological data suggest that P. univalens PDE transpires during the 2 to 32 cell stages, while Ascaris PDE occurs during the 4 to 16 cell stages. In both cases, PDE takes place in consecutive early embryo divisions in 5 independent pre-somatic cells (Fig 1B and 1C) [37]. In contrast, PDE in several other systems occurs in many cells at a single embryo division, such as the free-living nematode O. tipulae (fourth division) [56], the copepod Mesocyclops edax (fifth division), and the sea lamprey Petromyzon marinus (sixth division) [49]. It is unclear why organisms undergo PDE at different stages of embryogenesis and whether the timing of PDE is strictly associated with the transition from germline to somatic cells.
Cytological studies have revealed elements of chromosome behavior during Ascaris elimination mitoses. At metaphase, retained and eliminated DNA are both aligned at the metaphase plate. In early anaphase, the retained DNA segregates to the daughter cells while the eliminated DNA remains at the metaphase plate ( Fig 1C). In late anaphase, eliminated DNA breaks down into smaller pieces ( Fig 1D). The eliminated DNA stains with an antibody against H3S10P, a histone modification mark associated with condensed chromosomes during mitosis (Fig 1E-1G). Immunogold labeling of H3S10P for electron microscopy (EM) showed that the eliminated DNA is sequestered into double membrane-bound structures during telophase that resemble mammalian micronuclei [59]. The DNA likely undergoes autophagy and degradation in the subsequent cell divisions (Fig 1F and 1G) [41].
What sequences are eliminated during PDE? Early molecular cloning and cytological work showed that a large amount of DNA eliminated in P. univalens is associated with the HET arms ( Fig 1A) that consist of 5-and 10-mer repeats [60]. Likewise, eliminated DNA in Ascaris is mainly composed of 121-bp tandem satellite repeats [41,61]. These early observations lead to the assumption that PDE mainly eliminates repeats. However, seminal work indicated that at least 3 single-copy genes are eliminated in Ascaris [62][63][64]. Over the last decade, the Ascaris genome was sequenced and improved with multiple iterations using state-of-the-art technologies [38,40,41,65,66]. The latest version was built with long reads (PacBio) and 3D genome conformation data (Hi-C), resulting in 24 fully assembled germline chromosomes [41]. A comparison between the germline and the somatic genome enabled comprehensive identification of eliminated sequences, DNA breaks, and formation of new telomeres during Ascaris PDE [41]. Several significant findings emerged from these Ascaris genome analyses. First, all germline chromosome ends have a DSB in the subtelomeric region, resulting in the removal and remodeling of each chromosome end (Fig 2A and 2B) [41]. In addition, internal DSBs lead to an increased number of chromosomes from 24 in the germline to 36 in the somatic cells (Fig 2A). No genome rearrangements occur during Ascaris PDE [41]. Second, approximately 1,000 (5% of the total) genes are present in the eliminated DNA. These genes are expressed in the germline, primarily during spermatogenesis ( Fig 2C) [40,41]. Their elimination from the somatic cells suggests that PDE in Ascaris is an extreme gene silencing mechanism [38,40]. Third, telomeres are added to the broken DNA ends. The telomere addition sites occur within a 3 to 6 kb region called chromosomal breakage region (CBR). The CBRs appear to have no common motif or sequence features (see below), suggesting a sequence-independent mechanism of break site recognition [40]. Last, the CBRs and eliminated sequences are consistent among the 5 independent pre-somatic cells, between male and female worms, and between the human (A. lumbricoides) and pig (A. suum) parasites [40].
Most ascarid species undergo PDE [37]. How conserved is PDE among ascarids? A comparative genomic study identified approximately 1,000 eliminated genes in the horse parasite P. univalens and approximately 2,000 in the dog parasite T. canis [40]. About one-third of the eliminated genes are conserved among these 2 species and Ascaris ( Fig 2D). The conserved, eliminated genes in all 3 species are primarily expressed during spermatogenesis, suggesting a common mechanism for silencing testis genes in the somatic cells. Interestingly, the amount and composition of eliminated repetitive sequences varies drastically among the 3 species. Ascaris eliminates 121-bp repeats (10% of the genome) (Fig 2A and 2B), while P. univalens removes 5-bp and 10-bp repeats (89% of the genome), and T. canis throws away 49-bp satellite sequences (9% of the genome) [40]. The differences in tandem repeat composition may reflect their different origins and/or species-specific adaptions during nematode evolution.
In summary, Ascaris undergoes PDE in all 5 pre-somatic cells during the 4 to 16 cell stages. During PDE, 72 DSBs are introduced at specific sites (Fig 2A). The DSBs remove all chromosome ends and split germline chromosomes into smaller somatic chromosomes, thus increasing the number of chromosomes in the soma. During this process, approximately 18% of the germline genome is lost. The eliminated DNA is composed of satellite repeats and contains approximately 1,000 genes. Following DSB formation, all broken ends, including the ends of eliminated sequences, are healed with de novo telomere addition.

Molecular mechanisms of Ascaris PDE
What mechanisms are involved in PDE and how is the process regulated? Boveri noted that after centrifugation of P. equorum embryos, a "ball" of cytoplasmic factors would form at the PLOS PATHOGENS animal pole. The 2 blastomeres proximal to this ball would undergo PDE, while the 2 blastomeres distal to the ball would not. This led to the hypothesis of a cytoplasmic factor that induces PDE [44]. Subsequent studies by Moritz showed that UV irradiation of Parascaris embryos resulted in all cells undergoing PDE [44,67]. This suggests that a UV-sensitive factor is responsible for inhibiting PDE in germline cells. Experiments by Oliver and Shen, using dinucleated Ascaris embryos obtained by treatment with cytochalasin D (to prevent cytokinesis), further demonstrated that 1 blastomere always undergoes PDE while the other never does [68]. Together, these early experiments suggest a complex regulatory system where PDE-promoting factors associate with pre-somatic cells and PDE-inhibiting factors associate with germ cells [68]. These regulatory factors have yet to be identified.
At the molecular level, the process of PDE in Ascaris can be summarized in 4 major steps: (1) recognition of the sites for DNA breakage and generation of chromosome breaks; (2) healing broken DNA ends by telomere addition; (3) selective segregation of retained DNA; and (4) degradation of eliminated DNA (Fig 3A). It's not clear if these steps are coupled or if they are independent, sequential events. Overall, little is known about the molecular details of Ascaris PDE. Below, we summarize what is known and discuss possible molecular mechanisms involved in these steps.
How are break sites recognized and generated? Analysis of break regions for the presence of specific DNA sequences, structural motifs, palindromes, Z-DNA, and hairpins have revealed no apparent features that define or target CBRs for PDE break formation [41]. Additionally, no small RNAs or long non-coding RNAs appear to directly mark the break sites or contribute to PDE [66,69]. A recent analysis suggested that G-quadruplex DNA is enriched in extended (10 to 20 kb) regions covering 40 Ascaris CBRs [70]. However, G-quadruplexes are also enriched in other regions of the Ascaris genome, and many CBRs have no G-quadruplexes [70], suggesting G-quadruplex DNA is probably not a component of the CBRs.
One consistent feature of Ascaris CBRs is the increased chromatin accessibility before and during PDE, as measured by ATAC-seq ( Fig 3B) [40,41]. This accessibility may play a significant role in Ascaris PDE. In many systems, replication stress, transcription, and R-loop formation facilitate chromatin opening [71][72][73]. In addition, these factors are a source of genome instability and could lead to DSB formation [74]. Therefore, it is tempting to speculate that replication and transcription may be responsible for chromatin opening and DSB formation at Ascaris CBRs. The open chromatin may allow an endonuclease to access the CBR to generate the DSBs. In the free-living nematode O. tipulae, a conserved motif is necessary for the DNA break and telomere addition required for PDE [56]. In contrast, Ascaris CBRs have no common motif, thus a sequence-independent mechanism, such as 3D genome organization [75][76][77], may be needed to confine break formation to the CBRs.
How are the ends processed after a DNA break and how are telomeres added? Interestingly, genome sequencing indicates that 2 independent telomere addition sites are often observed in a single PDE event; the 2 sites are presumably from the 2 homologous chromosomes (Fig 3C) [40, 78,79]. In a population of Ascaris worms, telomere addition sites are randomly distributed within a constrained 3-to 6-kb region, which defines the CBRs (Fig 3C). This suggests the telomere addition sites are sequence-independent and random within the restricted genomic regions. Remarkably, telomere addition occurs not only to retained DNA but also to eliminated DNA [40, 78,79]. This indicates that telomere addition in Ascaris could be non-selective; it may heal all available PDE DNA breaks. This universal healing likely protects the broken DNA ends from undergoing fusions and genome rearrangements [36]. Analysis of these telomere addition sites has revealed that a single nucleotide of homology is sufficient for telomere addition in vivo [40]. Since the Ascaris telomeric repeat (TTAGGC) contains all 4 bases, the requirement of a single nucleotide means telomere addition can occur at any site within the CBRs. Telomerase activity from Ascaris cell-free extracts increases 10-fold from the one-cell to four-cell stage and remains elevated past the final PDE event [40,80]. This is consistent with RNA-seq data [81] and suggests telomerase is likely responsible for the synthesis of de novo telomeres during Ascaris PDE.
The telomere addition site is not necessarily the site where the initial DSB occurs. DSBs could occur at multiple sites within eliminated regions, adjacent to the CBRs followed by end resection, and/or at the site of telomere addition. Estrem and colleagues used END-seq, a technique that captures DSBs and end resections [82,83], to identify the position and timing of DNA breaks on synchronized embryos from before and during PDE stages [Estrem, Davis, and Wang, personal communications]. END-seq data identified that extensive resection occurs to generate 3 0 -overhangs necessary for telomere addition. This end resection is also conserved in O. tipulae PDE [56]. In addition, the timing of initial breaks detected by ENDseq suggests Ascaris chromosomes are broken prior to the onset of mitosis, consistent with EM observations [41]. This indicates that cellular mechanisms are required to congress eliminated chromosome fragments to the metaphase plate during DNA elimination mitosis (see Fig 1).

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associated with retained DNA [41]. In addition, 2 worm-specific Argonaute proteins (WAGOs) associated with endogenous small RNA (siRNA) pathways are differentially enriched in retained (WAGO-2) and eliminated (WAGO-3) DNA during PDE mitosis [Zagoskin, Wang, and Davis, personal communications]. It is unclear if these histone modifications or the WAGO argonautes are actively marking sequences for their retention/elimination or if they are an indirect consequence of PDE. For example, H3S10P on the eliminated DNA is likely due to a failure to dephosphorylate H3S10P as the eliminated DNA fragments are compartmentalized into micronuclei and may not progress through the normal metaphase to anaphase transition [41] (Fig 1F and 1G).
After the fragmentation of the chromosomes, how does the cell decide which chromosome pieces to keep and discard? Like the model nematode Caenorhabditis elegans, the chromosomes in Ascaris and P. univalens are holocentric, with multiple centromeres/kinetochores distributed along the length of the chromosomes, a feature that in principle makes DNA breakage more tolerable [39, 84,85]. Staining data demonstrated that during PDE, the histone H3 variant CENP-A, the epigenetic marker of centromeres, is absent in the DNA to be eliminated ( Fig  3D). This lack of centromeres in the eliminated DNA provides a mechanism for its subsequent loss after the DNA breaks, as no microtubules can attach to the DNA to facilitate its proper segregation during mitosis. ChIP-seq showed that CENP-A is evenly distributed across the genome in Ascaris male and female germlines [39]. These data suggest a dynamic reorganization of centromere deposition that enables Ascaris to selectively segregate the retained DNA into daughter nuclei while excluding the eliminated DNA (Fig 3D and 3E) [39]. The regulation of centromere reorganization has not been elucidated in Ascaris. However, transcription, histone modifications, and small RNAs have been linked to dynamic centromere deposition in fission yeast and nematodes [86][87][88].
How is eliminated DNA degraded? The enrichment of H3S10P on eliminated DNA provided a mechanism to track this chromatin following mitosis. H3S10P co-localizes with LGG1, an autophagosome marker [41]. Additionally, immuno-electron microscopy of H3S10P revealed many double membrane-bound structures are positive for H3S10P during the telophase following PDE (Fig 1F and 1G) [41]. These results suggest that, following mitosis, eliminated DNA is autophagocytosed into micronuclei-like structures. Large heterochromatic regions may take a few cell cycles to completely turn over, as remnants of the eliminated DNA from previous cell cycles are often seen in subsequent developmental stages (Fig 1D). The engulfment of the eliminated DNA into micronuclei may block the DNA from unnecessary repair and/or recombination events. Recent work has shown that micronuclei are prone to rupture, resulting in DNA fragmentation [89]. The mechanism of micronuclei fragmentation is not well understood, but aberrant replication or exposure to nucleases in the cytoplasm may drive this process [89][90][91]. Nematodes with PDE may provide a new model to study DNA fragmentation in micronuclei. For example, it will be interesting to determine if the DNA to be eliminated in Ascaris is turned over through an orderly or random process.

Functions of Ascaris PDE
The presence of PDE in phylogenetically diverse organisms suggests PDE may provide some selective advantage [43,45,49]. One consequence of PDE is the permanent removal of specific repetitive elements in all somatic cells, a common feature among all known species that undergo PDE [40, 55,56]. In Ascaris, 54% of the eliminated DNA consists of 121 bp tandem repeats. In addition, almost all satellite repeats (>99%) are eliminated from Ascaris, P. univalens, and T. canis [40]. These repeats likely have germline functions that are not needed (or are harmful) in the somatic cells. These functions could be related to meiotic chromosome pairing and recombination, spacing and scaffolding of 3D genome organization in the germline, and evolution of novel genes and/or chromosomes [41,45,[92][93][94][95]. Another benefit of removing repeats, particularly large amounts of satellites such as the 89% (2.2 Gb) eliminated from P. univalens, could be to downsize the genome, alleviating the burden of DNA replication and genome maintenance in somatic cells.
Another advantage of PDE could be the removal of germline-specific genes. Typically, germline genes in nematodes are silenced by histone modifications and small RNAs [96][97][98].
In Ascaris, most of the approximately 1,000 eliminated genes are expressed in the testis, ovary, or during early embryogenesis (Fig 2C) [38,40]. Thus, PDE provides a permanent means to silence these genes in the somatic cells. The removal of testis-expressed genes is conserved in the ascarids P. univalens and T. canis [6,40], further supporting the role of silencing germlineexpressed genes for PDE in ascarids. This gene silencing appears to be a common theme for PDE as germline-specific genes are identified in phylogenetically diverse species that undergo PDE [40,43,45,49]. In Ascaris, many of the eliminated genes have paralogs in the genome, including a germline-specific ribosomal protein [62,99] and translation initiation factors that are involved in mRNA translation [38,99]. Duplication of genes provides an alternative means of gene regulation. This is consistent with the model that an ancient genome duplication in the Ascaris lineage was balanced by PDE to compensate for gene dosage or to retain specific genes and thus their function after gene duplication [38].
What is the benefit of chromosome end removal and remodeling? Repetitive DNA and novel genes are often enriched at the ends of the nematode chromosomes, while more conserved and housekeeping genes are concentrated in the middle of the chromosomes [100]. All 13 Ascaris germline chromosomes with no internal PDE breaks have this sequence organization [41]. The other 11 germline chromosomes are believed to be potential fusions of multiple ancestral chromosomes (see below section on the evolution of PDE). Removal of repeats and novel genes from chromosome ends may protect the soma from potentially harmful sequences while allowing their existence in the germline. This may provide an evolutionary advantage for the germline to sample novel genes or harbor repeats. An alternative hypothesis is chromosome ends act as pairing centers that are needed in the germline but deleterious to the somatic cells. Consistent with this notion, proteins involved in C. elegans meiotic pairing [92][93][94][95] appear absent from Ascaris's genome [Wang, personal communications]. A recent study in the free-living nematode O. tipulae demonstrated a fail-safe mechanism is in place to ensure the removal of chromosome ends during PDE [56], emphasizing the importance of end removal for the biology of these species. Future studies are warranted to determine the functions of the eliminated DNA in the germline and the benefit of its removal in the somatic cells.
PDE clearly poses advantages in Ascaris and other nematodes. It is a mechanism to silence germline sequences and repetitive elements in the somatic genome. End removal and remodeling appear conserved among nematodes. In addition, PDE can alter the somatic chromosome karyotype, possibly leading to changes in the 3D genome organization and gene expression in the soma. These functions may provide an additional benefit to the survival and fitness of the organisms.

Evolution of PDE in nematodes
Comparative analysis of the Ascaris genome has revealed that 4 out of 5 sex chromosomes have undergone recent fusion events. These sex chromosomes are chimeric in their composition of Nigon elements (Fig 4A) [41,55]. Interestingly, the internally eliminated DNA represents the junction of presumptive fusion events on these sex chromosomes [41,55]. PDE splits these fused germline chromosomes into separate chromosomes in the somatic cells. Analysis

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of the fully assembled P. univalens germline and somatic genomes reveals that it has the same number (36) of somatic chromosomes as Ascaris [Simmons and Wang, personal communications]. The internally eliminated regions in both Ascaris and Parascaris have sequence features that are common to the ends of nematode chromosomes [85], including their enrichment of repeats, genes encoding hypothetical proteins, and genes specifically expressed in the testis. This suggests that these internal eliminated regions were likely originated from the ends of ancestral chromosomes. Thus, the current single germline chromosome of Parascaris and the 24 Ascaris germline chromosomes can be viewed as fusion products of the 36 ancient germline chromosomes. These ancestral germline chromosomes also likely underwent PDE with end remodeling (Fig 4B).
PDE in Ascaris and Parascaris provides a way to resolve these fused germline chromosomes to form the 36 somatic chromosomes. The reduced number of chromosomes in the germline should decrease the probability of segregation errors during meiosis. In comparison, the smaller somatic chromosomes may be more adapted to the conventional gene expression regulation in nematode, as the organization of the genes and repeats in these chromosomes resembles a typical nematode chromosome [85]. Thus, both fused germline chromosomes and split somatic chromosomes may pose advantages. Recent data from some free-living nematodes indicates internal breaks also occur [85]. This finding does not preclude PDE as a mechanism to resolve chromosome fusions in ascarids. Instead, it suggests that de novo introduction of DNA breaks in the middle of the chromosomes is possible, likely enabled by the holocentric nature of nematode chromosomes [85].
In nematodes, PDE has been discovered in 3 distinct clades, including many Oscheius species [55,56], Caenorhabditis monodelphis, and Mesorhabditis [57] from Clade V, ascarids (Ascaris, Parascaris Toxocara, and Baylisascaris) from Clade III [37], and Strongyloides [35, 101,102] from Clade IV. A common theme among Ascaris, P. univalens, and O. tipulae PDE is the removal of all chromosome ends, followed by new telomere addition. This leads to the question whether PDE is an ancient trait, or if it has convergently evolved in multiple nematode clades. It is known that the model organism C. elegans (Clade V) does not undergo PDE [103,104]. But how common is PDE among nematodes? Other nematodes may also remodel their chromosome ends with PDE, but the removal of only small amounts of DNA may have eluded detection due to technical limitations such as the sensitivity of cytological approaches and/or the requirement of telomere-to-telomere genome assemblies [55]. PDE may be more common or favored in nematodes because the holocentric nature of their chromosomes that allows fusions and fissions to be tolerated [105,106]. However, holocentromeres are not required for PDE as it is seen in several phyla with monocentric chromosomes [36, 45,49]. Nevertheless, end-remodeling appears to be a form of PDE that is often missed, suggesting PDE may be much more frequent than previously thought. Future identification of additional species with PDE will further elucidate the evolutionary relationship of PDE in various organisms.

Perspective
PDE violates the general view of genome constancy and integrity. However, PDE is a natural process found in many branches of animal phyla, suggesting its common presence and biological significance. The number of species described with PDE has increased with the use of genome sequencing and modern cytology. However, mechanistic insights into PDE are mostly limited to single-cell ciliates. For metazoans, the nematode group has been a leading model to study PDE since its discovery over 130 years ago. In particular, the large size of Ascaris, the ability to dissect specific germline and somatic tissues, and its slow, synchronous embryo development have enabled robust biochemistry, molecular biology, and genomics to be carried out. Other parasitic ascarids, including Parascaris and Toxocara, have also been used as comparative models to study PDE. Many features of PDE, including DNA breaks, telomere addition, and chromosome end removal and remodeling, are conserved in these nematodes [6,40]. The newly established PDE model in the free-living nematode O. tipulae now adds genetic and functional approaches to study PDE [56]. Overall, these studies will unveil the functions and mechanisms of PDE in nematodes, including the human parasite Ascaris.